CN106463321A - An x-ray device - Google Patents
An x-ray device Download PDFInfo
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- CN106463321A CN106463321A CN201580019030.XA CN201580019030A CN106463321A CN 106463321 A CN106463321 A CN 106463321A CN 201580019030 A CN201580019030 A CN 201580019030A CN 106463321 A CN106463321 A CN 106463321A
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- Prior art keywords
- ray generator
- generator according
- ray
- electronic emitter
- electronic
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Classifications
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J35/00—X-ray tubes
- H01J35/02—Details
- H01J35/04—Electrodes ; Mutual position thereof; Constructional adaptations therefor
- H01J35/06—Cathodes
- H01J35/065—Field emission, photo emission or secondary emission cathodes
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J35/00—X-ray tubes
- H01J35/02—Details
- H01J35/04—Electrodes ; Mutual position thereof; Constructional adaptations therefor
- H01J35/06—Cathodes
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N23/00—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00
- G01N23/02—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by transmitting the radiation through the material
- G01N23/04—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by transmitting the radiation through the material and forming images of the material
- G01N23/046—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by transmitting the radiation through the material and forming images of the material using tomography, e.g. computed tomography [CT]
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01V—GEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
- G01V5/00—Prospecting or detecting by the use of nuclear radiation, e.g. of natural or induced radioactivity
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J2201/00—Electrodes common to discharge tubes
- H01J2201/30—Cold cathodes
- H01J2201/304—Field emission cathodes
- H01J2201/30446—Field emission cathodes characterised by the emitter material
- H01J2201/30488—Nitrides
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J2201/00—Electrodes common to discharge tubes
- H01J2201/30—Cold cathodes
- H01J2201/304—Field emission cathodes
- H01J2201/30446—Field emission cathodes characterised by the emitter material
- H01J2201/30496—Oxides
Abstract
Example embodiments presented herein are directed towards an x-ray generating device. The device comprises at least one electron emitter (s) (22, 22_1, 22_2, 22_3) which has an electrically conductive substrate (23). The electrically conductive substrate comprises a coating of nanostructures (24). The device further comprises a heating element(21)attachable to each electrically conductive substrate. The device further comprises an electron receiving component (14) configured to receiving electrons emitted from the at least one electron emitter (s). The device also comprises an evacuated enclosure (10) configured to house the at least one electron emitter(s), the heating element and the electron receiving component. The at least one electron emitter (s) is configured for Schottky emission when the heating element is in an on-state and the at least one electron emitter (s) is negatively biased.
Description
Technical field
Illustrative embodiments presented herein are pointed to and are configured to behaviour under Schottky (Schottky) emission mode
The X-ray apparatus made.
Background technology
X-ray is bombarded metal surface and produced by high energy electron.In here setting, x-ray source includes 1) it is referred to as negative electrode
Electronic emitter, and 2) be referred to as target or anode electronic receiver device.Anode is X-ray emitter.Negative electrode
Arranged with specific configuration with anode and be encapsulated in vacuum cavity.Additionally, x-ray system may include with lower component:1) X penetrates
Line source, 2) computerization operation and processing meanss, 3) detector, and 4) power subsystem.Additionally, combining other technologies field, X
Ray can be applicable in imaging of medical, safety inspection and industrial nondestructive testing.Computer technology has revolutionized X-ray and has existed
Purposes in modern society, such as X-ray CT scanner (computed tomography).The development of detector technology allows energy to divide
The raising of resolution, digital picture and ever-increasing scan area.However, Cong Weilian Coolidge, Calvin (William
Coolidge) replace gas tube to revolutionize the generation of X-ray using thermionic emission with the vacuum tube equipped with hot tungsten filament
Mode, also both when the birth of Coolidge pipe since time of about 100 years in;The technology producing X-ray does not substantially have
There is innovation.
Content of the invention
Perhaps all X-ray tubes used in x-ray imaging all utilize the hot cathode of the tungsten filament based on thermionic emission.
At 10 years about of the past, people attempted being used CNT (CNT) as cold cathode to produce X-ray by Flied emission.
This electron emission is caused and need not be heated by highfield.CNT is considered as preferable electronic emitter.However, in x-ray source
Middle use, manufacture process and working condition seem to propose stern challenge to the material properties of CNT.Current output is still remote
Level less than practical application.Therefore, at least one purpose of illustrative embodiments presented herein is to provide other class
Electronic emitter, its can provide the method for corresponding electron emission with overcome in hot cathode and based on the cold cathode of CNT in intrinsic
Material and operation shortcoming, and therefore bring superior x-ray source.Additionally, illustrative embodiments presented herein can
Portable X-ray apparatus are provided.
Therefore, illustrative embodiments presented herein are pointed to using mixing transmitting (i.e. Flied emission or heat auxiliary electricity
Son transmitting) X-ray apparatus.Importantly, illustrative embodiments presented herein make use of Schottky to launch.Make
The disappearance on hot cathode and the performance of cold cathode can be compensated with hot aid electron emission.When launching to Schottky, thermoelectricity
When being compared between son transmitting and Flied emission, the benefit of illustrative embodiments will become more fully apparent.It is known that it is cold
Electronegative element such as S, Cl that negative electrode can be attracted to its surface destroy launching electronics characteristic, that is, occur in so-called negative electrode
Poison.If absorption is serious, negative electrode will stop launching electronics.For Flied emission X-ray tube, once intoxicating phenomenon occurs, can will penetrate
Spool splits out from machine and toasts in an oven, then installs back this pipe to check the effect of baking.This loaded down with trivial details mistake
Journey can make cold cathode regenerate.By contrast, for Schottky transmitting tube, the temperature rise in cathode surface appropriateness that heating leads to
Will assist in electron emission and prevent the poisonous gas atom of negative electrode absorption or molecule simultaneously.In the case of being poisoned, permissible
By directly heat negative electrode and need not by pipe from machine in split out and complete to regenerate.Relatively low power consumption will make required power supply more
Compact, so that X-ray apparatus become more portable.Additionally, can be saved using this electron emission mode based on heated filament being
Common cooling system in system, and shorten cooling and preheating cycle.
According to illustrative embodiments presented herein, point to the X-ray generation including at least one electronic emitter
Device, wherein, electronic emitter includes electrically-conductive backing plate.Electrically-conductive backing plate includes the coating of nanostructured.X-ray apparatus wrap further
Include the heating element heater that can be attached to each of at least one electronic emitter electrically-conductive backing plate.X-ray apparatus further include
It is configured to receive the electronic receipt part of the electronics from the transmitting of at least one electronic emitter.X-ray apparatus further include
It is configured to accommodate the vacuum cavity of at least one electronic emitter, heating element heater and electronic receipt part.Work as heating element heater
In an ON state and when at least one electronic emitter is negatively biased, at least one electronic emitter is arranged to
Schottky launches.
The example advantage of embodiment of above is, often eliminates in using thermionic emission based on the system of heated filament
The cooling system seen or long cooling and preheating period.Thus, it is possible to obtain more portable X-ray apparatus.
According to some illustrative embodiments, when heating element heater is off and at least one electronics generating means
When being negatively biased, at least one electronic emitter is further configured to Flied emission.
Therefore, according to this illustrative embodiments, X-ray apparatus can be configured to allow Flied emission and be based on
Both dual operational modes of transmitting of Schottky.The example advantage of this embodiment is that offer can be in various resolution
And contrast level provides the Versatile apparatus of radioscopic image.
According to some illustrative embodiments, X-ray apparatus may further include and are configured to control heating element heater
The power supply of running status.
For example, power supply can control the electron emission of at least one electronic emitter.Additionally, being sent out according at least one electronics
Emitter includes the illustrative embodiments of multiple electronic emitters, and power supply can be used for optionally activating different electron emission
Device.The example advantage of this embodiment is to provide more multiduty device, and the wherein separating component of this device can be single
Solely control.
According to some illustrative embodiments, power supply 28 is further configured to provide at least one electronics generating means
Potential difference and electronic receipt part between, for three bias mode (-, 0:Negative electrode is born, plus earth), (- ,+:Negative electrode
Negative, anode is just) and (0 ,+:Minus earth, anode is just) under diode.It is set using this bias mode to be used for causing
Schottky transmitting or Flied emission.
Therefore, the exemplary advantage of this embodiment is, eliminates in the system based on heated filament using Flied emission
In common cooling system or long cooling and preheating period.Thus, it is possible to obtain more portable X-ray apparatus.
According to some illustrative embodiments, it is constant (-, 0), (- ,+), (0 ,+) that power supply is configured in DC pattern, arteries and veins
Punch die formula i.e. Vp at anode>0 or at negative electrode Vp<0 square wave, or AC pattern be under sine wave operation.
The exemplary advantage providing the power supply with different operator schemes is to provide the ability of more general equipment.
For example, under pulse mode and AC pattern, it is possible to obtain the clear and definite rise time of waveform, frequency, dutycycle and pulse form
Shape.
According to some illustrative embodiments, electrically-conductive backing plate is by rustless steel, nickel, nickel-base alloy, ferrum or ferrous alloy system
Become.
According to some illustrative embodiments, nanostructured doping or composite mixed have including the row in the periodic table of elements
Doped chemical in IA, IIA, IB, IIIA, VIA or VIIA.
According to some illustrative embodiments, nanostructured is made up of ZnO.
The exemplary advantage of this embodiment is to provide the ability replacing the electronic emitter based on CNT.ZnO provides
Following example benefit:The electronic emitter more compatible with the transmitting based on Schottky is provided.Sent out based on the electronics of carbon
Emitter is easy to damage at the temperature of typical pipe manufacture process and active gas environment.But there is have equal with CNT
The field emission performance of captivation, ZnO and associated materials fusing point are high and chemical property is more stable.
According to some illustrative embodiments, electronic receipt part is by metal, metal alloy, metallic compound or metal
Ceramic composite is made.
Some illustrative embodiments are pointed to and are produced dress using X-ray described above in security X-ray scanning device
Put.
Some illustrative embodiments are pointed to and are produced dress using X-ray described above in ct apparatus
Put.
Some illustrative embodiments are pointed in C-arm type scanning device using X-ray generator described above.
Some illustrative embodiments are pointed in geologic prospect equipment using X-ray generator described above.
Some illustrative embodiments are pointed to and are produced dress using X-ray described above in X-ray fluorescence spectra analysis
Put.
Brief description
Will be apparent from from the middle the above that is discussed in greater detail of following exemplary embodiment, as shown in drawings, wherein
Run through the same reference character representation identical part of different views.Accompanying drawing is not necessarily drawn to scale, but focuses on illustrating
Illustrative embodiments.
Fig. 1 is the schematic diagram of the X-ray apparatus based on thermionic emission;
Fig. 2 is the schematic diagram of the X-ray according to illustrative embodiments described herein;
Fig. 3 is the illustrative of the electronic emitter with aperture plate according to some illustrative embodiments described herein
Example;
Fig. 4 be electronic emitter according to some illustrative embodiments described herein can have of different shapes
Illustrated examples;
Fig. 5 is the X-ray dress of the multiple electronic emitters of inclusion according to some illustrative embodiments described herein
The schematic diagram put;And
Fig. 6 A and Fig. 6 B is the electronic emitter illustrating the Fig. 5 according to some illustrative embodiments described herein
The figure of I-V characteristic.
Specific embodiment
In the following description, for illustrative purposes and without limitation, sets forth specific details such as concrete part, unit
Part, technology etc. are to provide the detailed understanding to illustrative embodiments.However, it is obvious for those skilled in the art
It is can to deviate these details and otherwise implement illustrative embodiments.In other instances, many institute's weeks are eliminated
Know method and element the description not obscure illustrative embodiments for the specific descriptions.Term used herein is used for retouching
The purpose stating illustrative embodiments is not intended to limit embodiment presented herein.
Illustrative embodiments presented herein point to the X-ray apparatus using the electron emission based on Schottky.
In order to preferably describe illustrative embodiments, will determine and call for Votes first.Fig. 1 illustrates traditional X-ray tube.The X of Fig. 1
Ray tube is characterised by the glass tube with vacuum 10 including hot filament cathode 12 and the anode 14 being made up of refractory metal/alloy.Anode
14 surface is with predetermined angle of inclination towards negative electrode 12.Filament 12 is passed through by the electric current that power supply 13 provides, promotes filament 12
Temperature is increased to the temperature from this filament launching electronics 16.Then the electronics of electron beam 16 is clashed into anode 14 by electric field acceleration.
This generates the X-ray beam 18 outside being transmitted into device via window 20.Voltage difference between negative electrode and anode determines X and penetrates
The energy of wire harness.
Perhaps all X-ray tubes used in x-ray imaging all utilize the hot cathode of the tungsten filament based on thermionic emission.
At 10 years about of the past, people attempted being used CNT (CNT) as cold cathode to produce X-ray by Flied emission.
This electron emission is caused and need not be heated by highfield.CNT is considered as preferable electronic emitter.However, as the moon
Use in the material x-ray source of pole, bulb manufacture process and working condition seem the material properties of CNT are proposed with choosing of sternness
War.The output current being currently based on the cold-cathode tube of CNT is still far below the level of practical application.Therefore, presented herein
At least one purpose of illustrative embodiments is to provide the electronic emitter of other class, and it can provide the side of corresponding electron emission
Method with overcome in hot cathode and based on the cold cathode of CNT in intrinsic material and operation shortcoming, and therefore bring superior X to penetrate
Line source.Additionally, illustrative embodiments presented herein can provide portable X-ray apparatus.
Therefore, illustrative embodiments presented herein are pointed to and are sent out using mixing transmitting, Flied emission or heat auxiliary
Penetrate the X-ray apparatus of Schottky transmitting.Specifically, illustrative embodiments presented herein are using being based on
The electron emission of Schottky.The lower power consumption that mixing transmitting leads to will allow using more compact power supply, so that X-ray dress
Put and become more portable.Additionally, eliminating based on common cooling system in the system of heated filament using this electron emission mode,
And cooling and preheating time can be shortened.
Fig. 2 illustrates the X-ray apparatus according to illustrative embodiments.The X-ray apparatus of Fig. 2 include comprising electronic emitter
The glass tube with vacuum 10 of (or negative electrode) 22 and electronic receipt part 14.The surface of electronic receipt part 14 is with predetermined inclination angle
Degree is towards electronic emitter 22.Heating element heater 21 is passed through by the electric current that power supply 28 provides, promotes the temperature liter of electronic emitter 22
Up to from the temperature of electronic emitter 22 divergent bundle 25.This transmitting is referred to as Schottky transmitting.With Fig. 1 by making
Compared with the electron emission that electrostatic field causes, the transmitting of Fig. 2 is caused by heating.
Then the electronics of electron beam 25 by electric field acceleration to electronic receipt part 14.This leads to be directed to dress via window 20
X-ray beam 26 beyond putting.Voltage difference between electronic emitter and electronic receipt part determines the energy of X-ray beam.
Electronic emitter 22 includes the electrically-conductive backing plate 23 comprising the coating of nanostructured 24.Heating element heater 21 the moon by pipe
The electric feedthrough of extreme two is attached to electrically-conductive backing plate 23.The coating of nanostructured 24 can be formed on electrically-conductive backing plate 23.Nanometer
Structure coating can be the form of nano-particle, nano wire, nanometer rods, four-acicular nanometer or nanotube.The material of substrate can
To be rustless steel, nickel, nickel-base alloy, ferrum or ferrous alloy.According to some illustrative embodiments, substrate is pre-formed into various shapes
Shape.
According to some illustrative embodiments, aperture plate 30 is placed on the surface 23 (including nanostructured 24) of electronic emitter
And electronic receipt part 14 (as extraction electrode) between, as shown in Figure 3.According to some illustrative embodiments, distance piece 31
It is placed between electronic emitter and aperture plate 30.Aperture plate can be placed on away from the electronic emitter 100um fixing via distance piece
At spacing distance to 1000um.Circular lid is placed on above aperture plate, as the grid providing voltage to aperture plate 30.Root
According to some illustrative embodiments, distance piece can be ceramic spacers.
Aperture plate is made up of isodiametric conductor wire.Additionally, wire by high-melting-point, low-steam pressure and conductive material such as W,
Mo, Ta, Ni, rustless steel or nickel-base alloy are made.The diameter of wire changes between 30um and 150um..The aperture efficiency of aperture plate
Change between 50% to 80%.Additionally, the surface-coated of the wire in aperture plate has has significant secondary electron emissions attribute
Thin layer or multilayer material, such as MgO and associated materials.Alternatively, coating be UV emissive material, GaN and
Associated materials.
Therefore this coating has the effect strengthening cathode electronics transmitting.As shown in figure 5, being applied to this of three pole x-ray tube
The overall advantage of the electron source of type is the multiplier effect independent of anode voltage and electric current output for the cathode current intensity.This
Outward, the electric field between negative electrode and grid determines emission current intensity;And the electricity between electronic emitter and electronic receipt assembly 24
Pressure reduction determines the energy of x-ray.
Fig. 4 shows the exemplary shape that electronic emitter can shape.Electronic emitter 22a is including electrically-conductive backing plate
The circular Pyramid of the coating of 23a and nanostructured 24a.Another example of electronic emitter 22b is set to equally wrap
Include the solid cylinder of the coating of electrically-conductive backing plate 23b and nanostructured 24b.Fig. 4 provides another example of electronic emitter, should
Electronic emitter is the form of the hollow cylinder 22c of the coating including electrically-conductive backing plate 23c and nanostructured 24c.Electronic emitter
Other example be set to the coating including electrically-conductive backing plate 23d and nanostructured 24d the star 22d of hollow form.Should
Work as understanding, because shape can affect the direction of the electronics of transmitting, so these shapes can adapt to the different purposes of X-ray.
It will be further understood that other shapes can also be applied in X-ray apparatus according to illustrative embodiments.
According to some illustrative embodiments, nano-structured coating can be sunk by solid-liquid-gas phase process, chemical vapors
Long-pending (CVD) processes or chemical solvent method generates.According to some illustrative embodiments, nano-structured coating is configured to
With respect to morphologic change, with generating process or afterwards further by chemistry, electrochemistry or optical meanss promotion electronics
Transmitting.
According to some illustrative embodiments, nano-structured coating can be by oxide, nitride, silicide, selenides
Or tellurides is made.According to some illustrative embodiments, nano-structured coating can be by oxide semiconductor such as ZnO system
Become.ZnO is N-shaped wide band gap semiconducter.Electrical conductivity is associated with the Lacking oxygen producing in generating process.
Carrying of electrical conductivity is realized by the element in row IA, IIA, IB, IIIA, VIA, VIIA of doped chemical periodic chart
High.Heat treatment after application growth is so that alloy is uniformly to surface or make them partly be segregated to surface.Nanostructured
Form can obtain Localized field enhancement by chemistry or electrochemical method change.UV can also be applied to process to improve surface
Performance.Face coat can be applied and further enhance electron emission to nanostructured with the work function by reducing emitter surface
Ability.According to some illustrative embodiments, can be by dielectric layer, such as SiO2, it is added on electrically-conductive backing plate and there is not nanometer
In the region of structure coating.This dielectric coat is useful to guiding electron emission.
When by heating element heater 21 appropriate heating, electronic emitter is negatively biased simultaneously, and electronics is sent out by Schottky
Penetrate to launch.When closing heating, negative electrode is negatively biased simultaneously, and electronics is launched by Flied emission.The heating function being added
(not existing in the Flied emission x-ray source of prior art) can also be applied in the cathode poison in the case of, by from transmitting
Device surface removes the chemical substance of undesired absorption and so that electronic emitter is regenerated.
According to some illustrative embodiments, X-ray apparatus can use multiple electronic emitters.Fig. 5 illustrates have
There is the X-ray tube of multiple electronic emitters.In this embodiment, three electronic emitter 22_1,22_2 and 22_3 groups
It is contained in sealed tube 10, and emitter facet is to electronic receipt part 14.The quantity and spacing of electronic emitter can change.
It should be appreciated that according to illustrative embodiments, X-ray apparatus can be applied any number of electron emission
Device.It will be further understood that the electronic emitter of Fig. 5 can be the electron emission with the feature of any one in Fig. 2 to Fig. 4
Device, or the emitter of any other shape.It is also understood that electronic emitter relative to each other do not need identical and can
To include different shapes and/or characteristic.
The pattern of the setting of electronic emitter can be but not limited to linear, rectangle, square, circular or hexagon.Phase
For the relation with electronic receipt part 14, electronic emitter 22_1,22_2 and 22_3 are arranged to all of which
Transmitting point to electronic receipt part 14 on a focus electronics 25a-25c, or make they by amplify or reduce
Transmitting pattern image project on electronic receipt part 14.
All these changes seek to fill that the requirement of the size and dimension of X-ray beam 26.Electronic emitter 22_1,22_2 with
And 22_3 activate can, simultaneously activate or Sequential Activation with collective's activation or individually.This flexible activation scheme is passed through to set
Determine the output frequency of power supply and allow X-ray to produce altofrequency, pulse mode, and by selecting the electronic emitter 22_ activating
1st, the quantity of 22_2 and 22_3 and in wider model selective radiation dosage.Electronic emitter 22_1,22_2 and 22_3 swash
Work can be controlled by power supply 28.
Illustrative embodiments presented herein allow individually to activate electronic emitter 22_1,22_2 and 22_3, from
And the mechanism for stablizing emission current is provided, this does not have in current x-ray system.It should be appreciated that in large area
In negative electrode or many negative electrodes, the inhomogeneities in transmitting are serious problems.This problem originates from the geometry of emitter
Inhomogeneities with physics.
In other words, the problem of emitter described above originates from material and technological problemses.Therefore, some exemplary enforcements
Mode points to improvement growth on substrate for the emitter materials.According to some illustrative embodiments, emitter when present in
Inhomogeneities are also resolved in component level.This exemplary by describing three cathode arrangement as the example in Fig. 5
Embodiment.
Fig. 6 A and Fig. 6 B illustrates the electric current of electronic emitter configuration and the voltage characteristic of Fig. 5.In each figure, by three
Angular, square and circular icon representation drawing point represents electronic emitter 22_1,22_2 and 22_3 of Fig. 5 respectively.
Fig. 6 A shows the making alive V when keeping the distance between electronic emitter and electronic receipt part identical.Each
Individual electronic emitter 22_1,22_2 and 22_3 will distinguish emission current i1, i2 and i3.As shown in the figure in Fig. 6 A,
The amount of the electric current being provided by the electron emission of each electronic emitter is different.Although inhomogeneities can pass through formal upper bound
The mean square deviation of the current value of the measurement of all emitters in fixed discussion or root-mean-square-deviation carry out quantificational description, but, Fig. 6 A
Shown in figure difference be enough to this point is shown.
If as from Fig. 6 B as can be seen that all three electronic emitter to launch identical electric current, then need by
Different voltage v1, v2 and v3 are respectively applied to electronic emitter 22_1,22_2 and 22_3.When these electronic emitters refer to
To different focuses with generate X-ray beam concrete shape when, show its advantage.This mechanism is passed through in all of focus
Place provides constant current to provide the spatially uniform of X-ray beam.Another advantage is that and point to one when these electronic emitters
When individual focus and successively bias, these emitters provide the electron emission with long-time uniformity, and it has perseverance in time
Determine electric current.Additionally, in order to ensure the stability of X-ray emission and uniformity, feedback monitoring circuit can be used for controlling electronics to send out
It is emitted through journey.
According to some illustrative embodiments, power supply 28 is further configured at least one electronics generating means and electronics
Between receiving part provide potential difference, for three bias mode (-, 0:Negative electrode is born, plus earth), (- ,+:Negative electrode is born, sun
Extremely just) and (0 ,+:Minus earth, anode is just) under diode.Being set using this bias mode is to cause
Schottky launches.Therefore, the exemplary advantage of this embodiment be to eliminate using Flied emission based on heated filament
Common cooling system or long cooling and preheating period in system.Thus, it is possible to obtain more portable X-ray apparatus.
According to some illustrative embodiments, it is constant (-, 0), (- ,+), (0 ,+) that power supply is operating as in DC pattern, arteries and veins
Punch die formula is plus earth or earthed-cathode square wave, or AC pattern is sine wave.There is provided and there are different operation modes
The exemplary advantage of power supply is to provide the ability of more general device.For example, under pulse mode and AC pattern, can obtain
Obtain clear and definite rise time, frequency, dutycycle and the pulse shape of waveform.
It should be appreciated that X-ray apparatus described herein can use in multiple fields.For example, X-ray apparatus are permissible
Safety check scanning device uses, for example, by the X-ray apparatus in airport security.Due to using heating element heater and
Schottky launches and more portable device is possibly realized it is possible to more easily implement in this safe examination system
X-ray apparatus.
Another example using X-ray apparatus described herein is in medical scanning means, and such as computer breaks
Layer (CT) scanning device or C-arm type scanning device, it can include type c-shape arm equipment.Penetrated using X described herein
Another example of line apparatus is in geologic prospect equipment.
It should be appreciated that X-ray apparatus described herein can use in arbitrary non-destructive detecting device.X-ray fills
The several exemplary application put can be molybdenum target inspection, veterinary's imaging and Xray fluorescence spectrometer etc..
The description of illustrative embodiments provided herein is for illustrative purposes.This description is not intended to exhaustive
Or illustrative embodiments are limited to published strict form, and can be modified according to teachings above
And modification, or modification and modification can be obtained by various replacements are implemented to the embodiment being provided.Select and describe
Example described herein, to explain principle and property and its practical application of various illustrative embodiments, so that this
Those of ordinary skill in field can be in every way and by being suitable for the various modifications of expected particular use Lai sharp
Use illustrative embodiments.The feature of embodiment described herein can be in method, equipment, module, system and calculating
Combine in all possible combination of machine program product.It should be appreciated that illustrative embodiments presented herein can be at that
Implement in this combination in any.
" include (comprising) " excluding the other elements beyond those listed or step it should be noted that word
Rapid presence, and the word " (a) " before element or " one (an) " are not excluded for the presence of multiple this elements.Also should
Work as attention, any reference number does not limit the scope of claim, and illustrative embodiments can be at least partially through hardware
Realize with software, and several " method ", " unit " or " device " can be represented by identical hardware branch.
In the accompanying drawings and the description it has been disclosed that illustrative embodiments.However, it is possible to make perhaps to these embodiments
Change and modifications more.Therefore, specific nomenclature despite the use of, but, they use only under general and descriptive meaning
Not for purposes of limitation, the scope of embodiment is determined by the claims that follow.
Claims (15)
1. a kind of X-ray generator, including:
At least one electronic emitter including electrically-conductive backing plate (23) (22,22_1,22_2,22_3), wherein, described electrically-conductive backing plate
Coating including nanostructured (24);
Heating element heater (21), can be attached to each described electrically-conductive backing plate of at least one electronic emitter described;
Electronic receipt part (14), is configured to receive the electronics from least one electronic emitter described transmitting;And
Vacuum cavity (10), is configured to accommodate at least one electronic emitter described, described heating element heater and described electronics
Receiving part;
Wherein, when described heating element heater is in an ON state and when at least one electronic emitter described is negatively biased, described
At least one electronic emitter is arranged to Schottky transmitting.
2. X-ray generator according to claim 1, wherein, when described heating element heater (21) is off simultaneously
And described at least one electronic emitter is when being negatively biased, described at least one electronic emitter (22,22_1,22_2,22_3)
It is further configured to Flied emission.
3. the X-ray generator according to any one of claim 1-2, further includes to be configured to control described adding
The power supply (28) of the running status of thermal element (21).
4. X-ray generator according to claim 3, wherein, described power supply (28) is configured at three
Under bias mode (-, 0), (- ,+) and (0 ,+), provide at least one electronics generating means described (22,22_1,22_2,
22_3) the potential difference and described electronic receipt part (14) between.
5. the X-ray generator according to any one of claim 3-4, wherein, described power supply (28) is configured to
Operate under DC pattern, pulse mode or AC pattern.
6. the X-ray generator according to any one of claim 1-5, wherein, described electrically-conductive backing plate (23) is by stainless
Steel, nickel, nickel-base alloy, ferrum or ferrous alloy are made.
7. the X-ray generator according to any one of claim 1-6, wherein, the doping of described nanostructured (24) or
Person is composite mixed to be had including the doped chemical in row IA, IIA, IB, IIIA, VIA or VIIA of the periodic table of elements.
8. the X-ray generator according to any one of claim 1-7, wherein, described nanostructured (24) is by ZnO system
Become.
9. the X-ray generator according to any one of claim 1-8, wherein, described electronic receipt part (14) by
Metal, metal alloy, metallic compound or ceramic-metal composite are made.
10. the X-ray generator according to any one of claim 1-9, wherein, at least one electronic emitter described
(22,22_1,22_2,22_3) further include the fixation being located between the 100um to 1000um separating by distance piece (31)
Aperture plate (30) at distance.
11. in security X-ray scanning device, using the X-ray generator according to any one of claim 1-10.
12. in ct apparatus, produce dress using the X-ray according to any one of claim 1-10
Put.
13. in C arm type scanning device, using the X-ray generator according to any one of claim 1-10.
14. in geologic prospect equipment, using the X-ray generator according to any one of claim 1-10.
15. in Xray fluorescence spectrometer, using the X-ray generator according to any one of claim 1-10.
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US201461937677P | 2014-02-10 | 2014-02-10 | |
US61/937,677 | 2014-02-10 | ||
PCT/EP2015/052788 WO2015118177A1 (en) | 2014-02-10 | 2015-02-10 | An x-ray device |
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CN106463321A true CN106463321A (en) | 2017-02-22 |
CN106463321B CN106463321B (en) | 2019-06-07 |
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CN201580019020.6A Active CN106463320B (en) | 2014-02-10 | 2015-02-10 | Electron emitter for X-ray tube |
CN201580019030.XA Active CN106463321B (en) | 2014-02-10 | 2015-02-10 | X-ray apparatus |
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US (2) | US10319555B2 (en) |
EP (2) | EP3105772B1 (en) |
JP (2) | JP6804304B2 (en) |
KR (2) | KR102313234B1 (en) |
CN (2) | CN106463320B (en) |
AU (2) | AU2015213991B2 (en) |
BR (2) | BR112016018369B1 (en) |
CA (2) | CA2939139A1 (en) |
MX (2) | MX363864B (en) |
RU (2) | RU2675791C2 (en) |
SA (2) | SA516371636B1 (en) |
WO (2) | WO2015118177A1 (en) |
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